This activity focuses on the relationship between science of looking for life and the tools, on vehicles such as the Mars Rover, that make it possible. Learners will create their own models of a Mars rover. They determine what tools would be...(View More) necessary to help them better understand Mars (and something about life on Mars/its habitability). Then they work in teams to complete a design challenge where they incorporate these elements into their models, which must successfully complete a task. Teams may also work together to create a large-scale, lobby-sized version that may be put on display in the library to engage their community. The activity also includes specific tips for effectively engaging girls in STEM. This is activity 6 in Explore: Life on Mars? that was developed specifically for use in libraries.(View Less)

This is an activity about spacecraft design. Teams of learners will model how scientists and engineers design and build spacecraft to collect, store, and transmit data to earth. Teams will design a system to store and transmit topographic data of...(View More) the Moon and then analyze that data and compare it to data collected by the Lunar Reconnaissance Orbiter .(View Less)

This is an activity about area and volume. Learners will use fabrication software to determine the optimal size of a satellite which can fit within a given rocket cylinder. To complete this activity, fabrication software is required (an example is...(View More) suggested in the lesson). This is the sixth activity as part of the iMAGiNETICspace: Where Imagination, Magnetism, and Space Collide educator's guide. Instructions for downloading the iBook educator's guide and the associated Transmedia book student guide are available at the resource link.(View Less)

This is an activity about using models to solve a problem. Learners will build four models of the MMS satellites using fabrication software. Their designs will based upon observations and data collected through prior activities (in the educator's...(View More) guide). To complete this activity, fabrication software is required (an example is given in the activity). This is the eighth and final activity as part of the iMAGiNETICspace: Where Imagination, Magnetism, and Space Collide educator's guide. Instructions for downloading the iBook educator's guide and the associated Transmedia book student guide are available at the resource link.(View Less)

This is an activity about using models to solve a problem. Learners will use a previously constructed model of the MMS satellite to determine if the centrifugal force of the rotating MMS model is sufficient to push the satellite's antennae outward,...(View More) simulating the deployment of the satellites after launch. Then, learners will determine the minimum rotational speed needed for the satellite to successfully deploy the antennae. This is the seventh activity as part of the iMAGiNETICspace: Where Imagination, Magnetism, and Space Collide educator's guide. Instructions for downloading the iBook educator's guide and the associated Transmedia book student guide are available at the resource link.(View Less)

This is a lesson about the solar wind, Earth's magnetosphere, and the Moon. Participants will work in groups of two or three to build a model of the Sun-Earth-Moon system. They will use the model to demonstrate that the Earth is protected from...(View More) particles streaming out of the Sun, called the solar wind, by a magnetic shield called the magnetosphere, and that the Moon is periodically protected from these particles as it moves in its orbit around the Earth. Participants will also learn that the NASA ARTEMIS mission is a pair of satellites orbiting the Moon that measure the intensity of solar particles streaming from the Sun.(View Less)

Learners will take and then compare the images taken by a camera - to learn about focal length (and its effects on field of view), resolution, and ultimately how cameras take close-up pictures of far away objects. Finally, they will apply this...(View More) knowledge to the images of comet Tempel 1 taken by two different spacecraft with three different cameras, in this case Deep Impact and those expected/obtained from Stardust-NExT. This lesson could easily be adapted for use with other NASA missions.(View Less)

Learners will become familiar with and use the engineering design process to sketch a reasonable drawing of the rover that will be built. The lesson uses the 5E instructional model and includes: TEKS Details (Texas Standards alignment), Essential...(View More) Question, Science Notebook, Vocabulary Definitions for Students, Vocabulary Definitions for Teachers, three Vocabulary Cards, and a concept map Mini-Lesson. teacher notes, vocabulary, student journal and reading. This is lesson 11 of the Mars Rover Celebration Unit, a six week long curriculum.(View Less)

This is a lesson about how to answer a scientific or engineering question. Learners will refine the scientific question they generated in Lesson 5 so that it can be answered by data and/or modeling, brainstorm possible solutions for the scientific...(View More) question chosen, determine reasonableness of solutions, use concept maps to enhance meaningful learning. The lesson uses the 5E instructional model and includes: TEKS Details (Texas Standards alignment), Essential Question, Science Notebook, Vocabulary Definitions for Students, Vocabulary Definitions for Teachers, two Vocabulary Cards, and a concept map supplement. This is lesson 6 of the Mars Rover Celebration Unit, a six week long curriculum.(View Less)

This is an assessment activity for the The Cosmic Ray Telescope for the Effects of Radiation (CRaTER) educational kit. Learners will make a poster that explains possible origins of cosmic rays, how they affect people, and what protects us here on...(View More) Earth. Alternately, they will make a poster describing CRaTER’s goal and how it works.(View Less)